Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

Suppose I have a function (it really does what the name says):

filter : ∀ {A n} → (A → Bool) → Vec A n → ∃ (λ m → Vec A m)

Now, I'd like to somehow work with the dependent pair I return. I wrote simple head function:

head :: ∀ {A} → ∃ (λ n → Vec A n) → Maybe A
head (zero   , _ )       = nothing
head (succ _ , (x :: _)) = just x

which of course works perfectly. But it made me wonder: is there any way I can make sure, that the function may only be called with n ≥ 1?

Ideally, I'd like to make function head : ∀ {A} → ∃ (λ n → Vec A n) → IsTrue (n ≥ succ zero) → A; but that fails, because n is out of scope when I use it in IsTrue.

Thanks for your time!

IsTrue is something like:

data IsTrue : Bool → Set where
  check : IsTrue true
share|improve this question
up vote 3 down vote accepted

I think this is a question about uncurrying. The standard library provides uncurrying functions for products, see uncurry. For your situation, it would be more beneficial to have a uncurry function where the first argument is hidden, since a head function would normally take the length index as an implicit argument. We can write an uncurry function like that:

uncurryʰ : ∀ {a b c} {A : Set a} {B : A → Set b} {C : (a : A) → B a → Set c} →
           ({x : A} → (y : B x) → C x y) →
           ((p : Σ A B) → uncurry C p)
uncurryʰ f (x , y) = f {x} y

The function that returns the head of a vector if there is one does not seem to exist in the standard library, so we write one:

maybe-head : ∀ {a n} {A : Set a} → Vec A n → Maybe A
maybe-head []       = nothing
maybe-head (x ∷ xs) = just x

Now your desired function is just a matter of uncurrying the maybe-head function with the first-argument-implicit-uncurrying function defined above:

maybe-filter-head : ∀ {A : Set} {n} → (A → Bool) → Vec A n → Maybe A
maybe-filter-head p = uncurryʰ maybe-head ∘ filter p

Conclusion: dependent products gladly curry and uncurry like their non-dependent versions.

Uncurrying aside, the function you want to write with type signature

head : ∀ {A} → ∃ (λ n → Vec A n) → IsTrue (n ≥ succ zero) → A

Can be written as:

head : ∀ {A} → (p : ∃ (λ n → Vec A n)) → IsTrue (proj₁ p ≥ succ zero) → A
share|improve this answer
Excellent, though I think you meant IsTrue (proj₁ p ≥ succ zero). – Vitus Mar 14 '12 at 15:59
Thank you, edited! – danr Mar 14 '12 at 16:01

The best way is probably to destructure the dependent pair first, so that you can just write:

head :: ∀ {A n} → Vec A (S n) → A

However, if you really want to keep the dependent pair intact in the function signature, you can write a predicate PosN which inspects the first element of the pair and checks that it is positive:

head :: ∀ {A p} → PosN p -> A

or similar. I'll leave the definition of PosN as an exercise to the reader. Essentially this is what Vitus' answer already does, but a simpler predicate can be defined instead.

share|improve this answer

After playing with it for some time, I came up with solution that resembles the function I wanted in first place:

data ∃-non-empty (A : Set) : ∃ (λ n → Vec A n) → Set where
  ∃-non-empty-intro : ∀ {n} → {x : Vec A (succ n)} → ∃-non-empty A (succ n , x)

head : ∀ {A} → (e : ∃ (λ n → Vec A n)) → ∃-non-empty A e → A
head (zero   , [])       ()
head (succ _ , (x :: _)) ∃-non-empty-intro = x

If anyone comes up with better (or more general) solution, I'll gladly accept their answer. Comments are welcome, too.

Here's more general predicate I came up with:

data ∃-succ {A : Nat → Set} : ∃ A → Set where
  ∃-succ-intro : ∀ {n} → {x : A (succ n)} → ∃-succ (succ n , x)

-- or equivalently
data ∃-succ {A : Nat → Set} : ∃ (λ n → A n) → Set where
share|improve this answer

This is just like the usual head function for Vec.

head' : ∀ {α} {A : Set α} → ∃ (λ n → Vec A (suc n)) → A
head' (_ , x ∷ _) = x
share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.